Etching apparatus and method

ABSTRACT

An etchant is supplied to a workpiece. Furthermore, the workpiece is irradiated with spatially modulated light to adjust a temperature profile of said workpiece while etchant is supplied.

TECHNICAL FIELD

The present application relates to etching apparatuses and methods foretching a workpiece.

BACKGROUND

In many industrial processes, workpieces, for example wafers, are etchedto change the form of the workpiece in some manner. For example, duringwafer processing and manufacture wafers, e.g., semiconductor wafers maybe etched, for example with the goal to level the wafer, i.e., reduce atotal thickness variation (TTV) of the wafer. To give an example, insome cases the wafer thickness influences electrical properties ofsemiconductor devices formed on the wafer, and therefore a smallthickness variation is desirable to reduce variations of the electricalproperties of manufactured semiconductor devices. For example, it isexpected that in the future thickness variations of ±1 μm will bedemanded for 8 inch wafers or even larger wafers.

To level the wafer, etching processes like spin etch processes where anetchant is dispensed on a rotating wafer, are used. For such and otheretching processes, it is desirable to locally control the etching rate.

SUMMARY OF THE INVENTION

According to an embodiment, a method is provided, comprising:

supplying an etchant to a workpiece to be etched, and

irradiating the workpiece with spatially modulated radiation to adjust atemperature profile of the workpiece while the etchant is being suppliedto the workpiece.

According to another embodiment, an apparatus is provided, comprising:

a radiation source, a spatial radiation modulator, an etchant supply anda workpiece holder as well as a control unit configured to control thespatial radiation modulator to modulate radiation from the radiationsource to a workpiece on the workpiece holder to adjust a temperatureprofile of the workpiece while the etchant is being supplied to theworkpiece from the etchant supply.

The above summary is merely intended to provide a short overview oversome features of some embodiments of the invention and is not to beconstrued as limiting, as other embodiments may comprise other featuresthan the ones indicated above.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram of an etching apparatus according to anembodiment;

FIG. 2 is a flow chart illustrating a method according to an embodiment;

FIG. 3A shows a schematic diagram of an apparatus according to anembodiment; and

FIG. 3B illustrates a part of an apparatus according to an embodimenttogether with an example for a light intensity distribution.

DETAILED DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS

In the following, embodiments of the present invention will be describedin more detail with reference to the attached drawings. However, it isto be noted that the scope of the invention is not limited to theembodiments shown in the drawings or described herein.

Features of different embodiments may be combined with each other unlessnoted otherwise. On the other hand, describing an embodiment with aplurality of features is not to be construed as indicating that allthose features are necessary for practicing the invention, as otherembodiments may comprise less features and/or alternative features.

The drawings are provided to give an understanding of the embodimentsrepresented, and therefore various elements shown in the drawings arenot necessary to scale with each other. Any directional references tothe drawings like top, bottom, left or right are merely chosen asconvenient for referring to various elements in the drawings and are notto be construed as indicating an actual location of the elements inimplementations of the embodiments.

Turning now to the figures, FIG. 1 illustrates an etching apparatus 10for etching a workpiece 15 according to an embodiment. Workpiece 15 mayfor example be a semiconductor wafer like a silicon wafer, but may alsobe any other workpiece to be etched, for example a semiconductorworkpiece other than a wafer or a metal workpiece.

Etchant may be sprayed or dispensed on workpiece 15 from an etchantsupply 17 via a nozzle 18, while workpiece holder 16 rotates workpiece15 about a rotational axis 112. The etchant thus supplied may beselected depending on the kind of workpiece 15 to be etched, for exampledepending on the material of workpiece 15. Any conventional etchant usedfor the respective material may be used, for example an etchant based onpotassium hydroxide in case of silicon to be etched. In someembodiments, in case of a rotating workpiece holder nozzle 18 may havean opening on rotation axis 112 to supply etchant centrally to thewafer.

In other embodiments, etchant may be supplied in a different manner toworkpiece 15. For example, workpiece 15 may be submersed in an etchantprovided in an etching bath 111, just to give an example for a differentway of supplying etchant.

Etching apparatus 10 further comprises a radiation source, e.g., a lightsource 11 which emits light beams 12 and a light modulator 13 whichspatially modulates light beams 12 to become spatially modulated lightbeams 14 irradiating workpiece 15. In particular, through lightmodulator 13 the light intensity, i.e., the power, on workpiece 15 maybe spatially modulated such as to locally heat workpiece 15. Lightsource 11 may be any suitable light source, for example a white lightsource, which emits light of sufficient power which is sufficientlyabsorbed by workpiece 15. For example, in an embodiment workpiece 15 isintransparent to light emitted by light source 11. In case of aworkpiece made of silicon, light source 11 may for example emit light inthe visible range. A power of light source 11 may be selected such thata maximum light intensity on workpiece 15 is at least 1 W/cm², forexample at least 5 W/cm².

Light modulator 15 may be any kind of light modulator which allows aspatial modulation of the light intensity on workpiece 15, for examplein an adjustable manner. Light modulator 13 may for example comprise amicromirror array, for example a digital micromirror device (DMD) like adigital light processing (DLP) chip. In such a case, each micromirroreither guides light to workpiece 15 or prevents light from reachingworkpiece 15. By providing an array of such micromirrors, the spatiallight distribution on workpiece 15 may be controlled by actuating theindividual micromirrors accordingly. Such micromirrors may for examplebe implemented as microelectromechanical systems (MEMS). In otherembodiments, a LCD (Liquid Crystal Display) array may be used, whereindividual pixels of the display may be either transparent orintransparent to light depending on a control signal. In case anadjustable control of the spatial distribution is not needed, forexample also a mask may be used to provide a fixed spatial modulation.

By modulating the light intensity, as already mentioned above, workpiece15 may be locally heated while etchant from etchant supply 17 issupplied to workpiece 15 via nozzle 18. Supplying the etchant providessome measure of cooling to workpiece 15, which for example may preventoverheating and/or may establish a stable temperature distribution onworkpiece 15. By locally heating workpiece 15, an etching rate of thesupplied etchant may be controlled. Like most chemical reactions, thechemical reaction underlying the etching process istemperature-depending. Typically, for example an increase of thetemperature of 10° C. may double the etching rate. Therefore, even bylocally heating the workpiece 15 only by some ° C., for example 2 or 3°C., the etching rate may be influenced in a significant manner.

Light modulator 13 in the embodiment of FIG. 1 is controlled by acontrol unit 19 which sets a desired light intensity profile to obtain adesired temperature profile and thus a desired etching ratedistribution. For example, etching rates may be varied by controllinglight modulator 13 accordingly to level workpiece 15, i.e., to increasethe flatness, for example by increasing the etching rate at thickerportions of workpiece 15. In some embodiments, a measurement device 110may be provided for obtaining a thickness profile of workpiece 15.Suitable measurement devices 110 may for example operate based oncapacitive measurements, optical triangulation or interference-basedmeasurements. Such measurements may for example be performed prior tothe etching process, and control unit 19 may then control lightmodulator 13 based on a measured thickness profile and a look-up tableor other calibration stored in control unit 19 to set the spatial lightdistribution accordingly. In some embodiments, workpiece 15 may again bemeasured after the etching, and the above-mentioned look-up table orother calibration may be adapted according to the results. For example,if the measurement after the etching shows that an etching rate was toolow at a certain spot based on the calibration, for a next workpiece thelight intensity in a similar situation may be increased to increase thetemperature and therefore etching rate. Conversely, when an etching rateis found to be too high, the light intensity may be decreased todecrease the temperature and thus the etching rate. In some embodiments,a measurement may also be performed during etching, and the lightintensity may be adjusted during the etching to obtain a desired etchingprofile.

Control unit 19 may be any kind of suitable computing device, forexample a computer.

It should be noted that in embodiments where workpiece holder 16 rotatesworkpiece 15, light modulator 13 may in some embodiments only beprovided on one side of axis 112 to illuminate a strip or line onworkpiece 15. By the rotation, then the complete workpiece is irradiatedwith radiation from light source 11. In such embodiments, for examplerotationally symmetric irradiation patterns and therefore rotationallysymmetric temperature profiles may be obtained.

In FIG. 2 a flowchart illustrating a method according to an embodimentis shown. The method illustrated in FIG. 2 may be implemented in theapparatus of FIG. 1, but may also be implemented in other etchingapparatuses.

At 20, a thickness profile of a workpiece is measured. For example, acapacitive measurement, optical triangulation or an interference-basedmeasurement or other measurements conventionally used in the art forobtaining thickness profiles may be used.

At 21, etchant is supplied to the workpiece, for example dispensed ontothe workpiece while the workpiece is rotated, and at 22 during thesupplying of etchant the workpiece is irradiated by spatially modulatedradiation to adjust a temperature profile of the workpiece based on themeasurement at 20. For example, in case the workpiece is to be leveled,radiation intensity may be higher at thicker portions of the workpieceand lower at thinner portions of the workpiece. The temperature profilemay be a rotationally symmetric temperature profile, for example whenthe workpiece is rotated during the supplying of the etchant.

It is also to be noted that supplying the etchant provides a cooling tothe workpiece in some cases, and the cooling via the etchant togetherwith heating by the radiation may lead to a stable temperature profile.

At 23, the workpiece is measured again. This measuring at 23 may in someembodiments be performed simultaneously to the etching process at 21and/or 22, and the supplying of etchant and the irradiation, inparticular the modulation, may be modified based on the measuring at 23until a desired profile is reached. In other embodiments, the measuringat 23 is performed after the etching process at 21, 22. In someembodiments, when the results of the measurement at 23 are notsatisfying, for example if a profile after etching does not match anintended profile sufficiently, the workpiece may again be subjected toan etching with irradiation, i.e., the operations described with respectto 21 and 22 may be repeated. In other embodiments, after the measuringof the workpiece at 23, a next workpiece is processed starting at 24(for which then the operations described with respect to 20 to 23 areperformed) and the results of the measurement at 23 may be used forimproving parameters like the spatial modulation of the radiation forthe next workpiece.

In FIG. 3, an apparatus according to a further embodiment is shown, FIG.3A showing the complete apparatus and FIG. 3B showing a part thereoftogether with an example for an intensity profile. The embodiment ofFIG. 3 comprises a high power light source 30 emitting light toirradiate and thus heat a workpiece 36, for example a wafer. Betweenhigh power light source 30 and workpiece 36 a DLP chip 31 is providedserving as a light modulator. In other words, via DLP chip 31 thespatial distribution of light intensity on workpiece 36 may bemodulated. In the example shown, toward the left a higher lightintensity corresponding to a higher intended temperature is present, andto the right a lower intensity corresponding to a lower temperature ispresent. Workpiece 36 may for example be a wafer on a chuck 38 acting asa rotating wafer holder onto which an etchant is dispensed, for exampleas explained with reference to FIG. 1. In this case, the left part ofworkpiece 36 may represent the center of the wafer, and the right partmay represent the periphery of the wafer.

An example for a resulting intensity profile is shown as a curve 33 inthe lower half of FIG. 3B and as a greyscale profile 32, darker greys inprofile 32 denoting a higher intensity. In this example, a radiallysymmetric intensity distribution is assumed, which for example may beachieved using a rotating workpiece holder and thus a rotating workpieceas explained above. In this example, from a center of the workpiece(radius 0) the intensity first increases and then drops again towardsthe edge of the workpiece.

As can be seen in FIG. 3A, workpiece 36, for example a semiconductorwafer, for which intensity profile 32, 33 as shown as an example in FIG.3B is obtained, is provided on chuck 38 between pins 37. An etchantdispenser 34 which may be movable in a plane parallel to a surface ofworkpiece 36 dispenses etchant 35 onto the workpiece. Inside chuck 38, achannel 39 is provided through which gas, for example nitrogen, may besupplied such that workpiece 36 rests on a gas cushion, for example anitrogen cushion. As indicated in FIG. 3A, chuck 38 in the embodimentshown in rotatable.

As also shown in FIG. 3A, with high power light source 38 and DLP chip31 only one side of wafer 36 in the cross-sectional view is irradiated(for example in form of a strip or line on workpiece 36), and throughthe rotation of chuck 38 a rotationally symmetric temperature profilemay be obtained. However, it should be noted that in other embodimentsno rotation is provided, and for example essentially a complete face,for example an upper surface or even more than one face may beirradiated to obtain a desired temperature profile.

It should further be noted that rotationally symmetric thicknessprofiles in some industrial processes are often present, as for exampleduring wafer manufacture also other processes like grinding, lapping,Taiko grinding or mounting are rotationally symmetric processes.

It should be noted that in some embodiments the etchant used may be anon-photoactive etchant, i.e., an etchant which does not require lightfor the etching process. In other embodiments, the etching reaction maybe a photochemical reaction activated by light. In this case, in someembodiments light from light source like high power light source 30 ofFIG. 3 or light source 11 of FIG. 1 may be used to activate the etchingprocess as well as for heating the wafer. In other embodiments, thelight source of the embodiment described may emit light in a range notusable for activating the etching reaction such that the light source isonly used to heat the wafer to establish a desired temperature, and anadditional light source may be provided to activate the etchingreaction. In such an embodiment, the actuation of the etching reactionand the temperature may be controlled separately.

While light has been used as an example for radiation in the embodimentsabove, it should be noted that radiation of any spectral range suitablefor heating a respective workpiece may be used, e.g., infraredradiation.

As already emphasized, the above embodiments serve only as examples forillustrating some possibility of implementing the present invention, andthe present invention is not restricted to these possibilities.

What is claimed is:
 1. An apparatus comprising: a workpiece holder; anetchant supply configured to supply etchant to a workpiece held by saidworkpiece holder; a radiation source; a spatial radiation modulatorconfigured to spatially modulate radiation emitted from said radiationsource to said workpiece; and a control unit configured to control saidspatial radiation modulator to establish a desired temperature profileon said workpiece while etchant is supplied to said workpiece.
 2. Theapparatus of claim 1, wherein said radiation source has a powersufficient to irradiate said workpiece with a power density of at least1 W/cm².
 3. The apparatus of claim 1, further comprising a measurementdevice configured to measure a thickness profile of said workpiece. 4.The apparatus of claim 3, wherein said measurement device is configuredto perform at least one of a capacitive measurement, an opticaltriangulation or an interference based measurement.
 5. The apparatus ofclaim 3, wherein said control unit is configured to control said spatialradiation modulator based on a measurement result of said measurementdevice.
 6. The apparatus of claim 1, wherein said workpiece holder isrotatable.
 7. The apparatus of claim 6, wherein said radiation sourceand said spatial radiation modulator are arranged to irradiate saidworkpiece on said workpiece holder only on one side of a rotation axisof said workpiece holder.
 8. The apparatus of claim 1, wherein saidspatial radiation modulator comprises at least one of a micromirrorarray or a liquid crystal display array.
 9. An apparatus comprising: arotatable chuck; an etchant dispenser arranged above said chuck; a highpower light source; and a light modulator arranged between said highpower light source and at least part of said chuck to control atemperature of a workpiece on said chuck.
 10. The apparatus of claim 9,wherein said chuck comprises a channel for establishing a gas cushionbetween said workpiece and said chuck.
 11. The apparatus of claim 9,wherein said light modulator is arranged on one side of a rotation axisof said chuck.
 12. The apparatus of claim 9, wherein said dispenser ismovable in a direction parallel to a surface of said chuck.
 13. Theapparatus of claim 9, wherein said high power light source has a powercapable of irradiating said chuck with a power density of at least 1W/cm².
 14. The apparatus of claim 9, wherein said light modulatorcomprises a digital light processing (DLP) chip.